Synthesis and characterization of heterogeneous rhenium and molybdenum catalysts : applications in olefin metathesis and olefin epoxidation /

Veljanovski, Draganco.

January 2009

Zugl.: München, Techn. University, Diss., 2009.

Asymmetrische Weitz-Scheffer-Epoxidierung mit optisch aktiven Hydroperoxiden oder Phasentransferkatalysatoren

Degen, Hans-Georg.

January 2002

Würzburg, Univ., Diss., 2002.

Heterogeneously catalyzed reactions with vegetable oils: epoxidation and nucleophilic epoxide ring-opening with alcohols

Rios, Luis Alberto.

Unknown Date

Techn. Hochsch., Diss., 2003--Aachen.

Estereo e sitio seletividade da epoxidação de diferentes terpenos com AI2O3 obtida via sol-gel / Stereo and site selectivity in the epoxidation of terpenes with alumina obtained the sol-gel process

Souza e Silva, Juliana Martins de

08 December 2005

Orientador: Ulf Friedrich Schuchardt / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-05T11:23:00Z (GMT). No. of bitstreams: 1 SouzaeSilva_JulianaMartinsde_M.pdf: 1388299 bytes, checksum: 458da63b650d37e689b58c29b1f89d7d (MD5) Previous issue date: 2005 / Mestrado / Quimica Inorganica / Mestre em Química

Epoxidação

Terpenos

Sol-gel

Alumina

Epoxidation

Terpenes

Characterization of Recombinant Chloroperoxidase, and F103A and C29H/C79H/C87H Mutants

Wang, Zheng

08 April 2011

Mechanistically and structurally chloroperoxidase (CPO) occupies a unique niche among heme containing enzymes. Chloroperoxidase catalyzes a broad range of reactions, such as oxidation of organic substrates, dismutation of hydrogen peroxide, and mono-oxygenation of organic molecules. To expand the synthetic utility of CPO and to appreciate the important interactions that lead to CPO’s exceptional properties, a site-directed mutagenesis study was undertaken. Recombinant CPO and CPO mutants were heterologously expressed in Aspergillus niger. The overall protein structure was almost the same as that of wild type CPO, as determined by UV-vis, NMR and CD spectroscopies. Phenylalanine103, which was proposed to regulate substrate access to the active site by restricting the size of substrates and to control CPO’s enantioselectivity, was mutated to Ala. The ligand binding affinity and most importantly the catalytic activity of F103A was dramatically different from wild type CPO. The mutation essentially eliminated the chlorination and dismutation activities but enhanced, 4-10 fold, the epoxidation, peroxidation, and N-demethylation activities. As expected, the F103A mutant displayed dramatically improved epoxidation activity for larger, more branched styrene derivatives. Furthermore, F103A showed a distinctive enantioselectivity profile: losing enantioselectivity to styrene and cis-β-methylstyrene; having a different configuration preference on α-methylstyrene; showing higher enatioselectivites and conversion rates on larger, more branched substrates. Our results show that F103 acts as a switch box that controls the catalytic activity, substrate specificity, and product enantioselectivity of CPO. Given that no other mutant of CPO has displayed distinct properties, the results with F103A are dramatic. The diverse catalytic activity of CPO has long been attributed to the presence of the proximal thiolate ligand. Surprisingly, a recent report on a C29H mutant suggested otherwise. A new CPO triple mutant C29H/C79H/C87H was prepared, in which all the cysteines were replaced by histidine to eliminate the possibility of cysteine coordinating to the heme. No active form protein was isolated, although, successful transformation and transcription was confirmed. The result suggests that Cys79 and Cys87 are critical to maintaining the structural scaffold of CPO. In vitro biodegradation of nanotubes by CPO were examined by scanning electron microscope method, but little oxidation was observed.

chloroperoxidase. enantioselectivity

site-directed mutagenesis

epoxidation

F103A

Helical transition metal complexes:synthesis, characterization and asymmetric epoxidations.

Liu, Tingting

January 1900

Doctor of Philosophy / Department of Chemistry / Christopher J. Levy / A series of chiral titanium and manganese complexes with helix-directing salen ligands have been prepared, characterized and studied. Their structures displayed as a chiral helical motif as expected. And it was also found that all M(salen) units were exclusively M-helimeric in the solid state, except Ti(cyclohexyl-benz[a]anthryl) as P-helix. This may be due to the energy difference between P and M helice, which enables crystal packing forces to control and drive the molecular structure. This is also in agreement with the previous computational studies that the M configuration predominates in THF solution. All metal centers adopt a cis-β octahedral geometry except in Mn(binapthyl-phenanthryl-salen). Most of M(salen) complexes in this work afforded μ–oxo dinuclear helicates, instead of the expected monohelicate, except Mn(binapthyl-phenanthryl-salen), which is bridged by a third salen ligand. The titanium salt affected the complex solution behavior. In the presence of Cl[superscript]-, only mononuclear species was found by ESI-MS, while both di- and mononuclear species was found in MeOH in the presence of –O[superscript]iPr. The NMR spectra of Ti(salen) indicated one major species with cis-β geometry exist in most solution, which could be monomer or dimer, except Ti(binapthyl-salen). No counterions have been found in the solid state of Mn(salen) complexes in this work, but they affected the ligand decomposition in the solution in Mn(binapthyl-phenanthryl-salen). The Mn(salen) complexes could effectively and enatioselectively catalyze the asymmetric epoxidation of somoe trans, cis and terminal olefin, and various oxidants were employed.

Transition metal complex

Asymmetric epoxidation

Chemistry (0485)

Inorganic Chemistry (0488)

Chiral auxiliaries and substrate directable reactions to access highly functionalised chiral lactones

Davies, Iwan Rhydian

January 2009

This thesis describes the development of chiral auxiliary based methodologies for the asymmetric synthesis of hydroxylated !-lactones and "-lactones containing multiple contiguous stereocentres. The first chapter introduces the concept of chirality and provides a general overview of the range of strategies available for the preparation of chiral molecules in enantiomerically pure forms. The second chapter critically reviews the range of synthetic methodology that is currently available for the asymmetric synthesis of chiral #-lactones that are either natural products or useful chiral building blocks for synthesis. The third chapter describes the development of novel methodology for the epoxidation/lactonisation of a range of $-vinyl-syn-aldols to directly afford !-lactones containing up to four contiguous stereocentres in high de. These reactions were shown to proceed via a mechanism whereby hydroxyl-directed diastereoselective epoxidation is followed by intramolecular attack of their !-acyl-oxazolidin-2- one fragment, to directly afford the desired chiral !-lactone. The ‘self-cleavage’ aspect of these reactions was exploited to enable this methodology to be transferred to polymer-support using an immobilised Evans’-oxazolidin-2-one for asymmetric synthesis. Chapter 4 describes the development of a complementary methodology for the asymmetric synthesis of this type of hydroxylated !-lactone based on a strategy involving dihydroxylation of N-acyl-oxazolidin-2-one-$-vinyl-syn-aldols using catalytic amounts of osmium tetroxide. This methodology was developed as part of a reinvestigation of previously reported dihydroxylation reactions by Dias and coworkers, where we have clearly shown that the stereochemistry of thelactones reported in their paper have been incorrectly assigned. This diastereoselective dihydroxylation methodology has been successfully applied to the asymmetric synthesis of the natural product deoxyribonolactone. Finally, Chapter 5 describes the development of methodology for the asymmetric synthesis of chiral "-lactones containing four contiguous stereocentres of use as potential chiral building blocks for the synthesis of polyketide natural products. In this approach, cyclopropanation of N-acyl-oxazolidin-2-one-$-vinyl-syn-aldols occurs under the sterodirecting effect of the $- hydroxyl group to afford cyclopropyl-aldols in very high de. These cyclopropyl-aldols are then ring opened in the presence of mercuric ions, with their N-acyl-oxazolidin-2-one fragment acting as an internal nucleophile, to afford highly functionalised alkyl-mercury species that may be subsequently reduced to afford their corresponding "-lactones in high de.

547.1223

Mn(salen)- und Fe(porph)-katalysierte enantioselektive Epoxidierungen / Mn(salen)- and Fe(porph)-catalyzed enantioselective epoxidations

Roschmann, Konrad J.

January 2002

Ziel der vorliegenden Arbeit war es zum einen, das Potential von chiralen Eisenporphyrin- und Mangansalen-Katalysatoren zur kinetischen Racematspaltung sekundärer Allylalkohole durch asymmetrische Epoxidierung auszuloten. Zum anderen sollten Untersuchungen zum Mechanismus der Jacobsen-Katsuki-Epoxidierung durchgeführt werden; ein besonderes Augenmerk lag dabei auf der Fragestellung, welche Faktoren dazu führen, dass bei der Umsetzung von cis-Olefinen ein Gemisch aus cis- und trans-Epoxiden erhalten wird. Eine Auswahl arylsubstituierter Allylalkohole IIa-f wurde mit den Katalysatoren Ia und Ib,c und 0.8 bzw. 0.6 Äquivalenten an Iodosobenzol als Sauerstoffdonor umgesetzt (Gl. I), wobei es zu einer kinetischen Racematspaltung kommt. Die Oxidation verläuft für beide Katalysatorsysteme sowohl chemoselektiv (vorwiegend Epoxidierung) als auch diastereoselektiv (dr bis zu > 95:5). Als Hauptprodukte werden für die offenkettigen Allylalkohole IIa,e,f die threo-konfigurierten Epoxyalkohole III erhalten, während die cyclischen Allylakohole IIb-d die entsprechenden cis-Epoxyalkohole III lieferen. 1,1-Dimethyl-1,2-dihydro-2-naphthol (IIc) ist hierbei eine Ausnahme, da die CH-Oxidation dieses Substrats eine beachtliche Nebenreaktion darstellt. Der Hauptunterschied zwischen den Fe- und Mn-Katalysatoren liegt in der Enantioselektivität: Während mit dem Fe(porph*)-Komplex Ia nur Selektivitäten von maximal 43 Prozent ee (krel = 2.7) erzielt werden, erwiesen sich die Mn(salen*)-Komplexe Ib,c als geeignete Katalysatoren, mit denen ee-Werte von bis zu 80 Prozent (krel = 12.9) erreicht werden. Die in der kinetischen Racematspaltung erzielten Selektivitäten können durch ein synergistisches Zusammenwirken von hydroxy-dirigierendem Effekt einerseits und sterischen Wechselwirkungen zwischen Substrat und Eisen-Komplex oder, im Falle des Mangan-Komplexes, Angriff des Olefins entlang der so genannten Katsuki-Trajektorie andererseits erklärt werden. Fazit: Die chiralen Mn(salen*)-Komplexe Ib,c sind wirkungsvolle Katalysatoren für die asymmetrische Epoxidierung racemischer sekundärer Allylalkohole II. In exzellenten Chemo- und Diastereoselektivitäten entstehen die entsprechenden Epoxyalkohole III mit ee-Werten bis zu 80 Prozent. Die zurückbleibenden Allylalkohole werden dabei bis zu 53 Prozent ee angereichert. Im Vergleich dazu weist der Eisenkomplex Ia eine ungleich geringere Enantioselektivität auf. Mechanistische Untersuchungen mit Vinylcyclopropan Va ergeben, dass die Jacobsen-Katsuki-Epoxidierung nicht über ein kationisches, sondern über ein radikalisches Intermediat abläuft. Dies wird anhand von Produktstudien durch reversed phase-HPLC-Analytik belegt. In weitergehenden Untersuchungen mit cis-Stilben (Vb) und cis--Methylstyrol (Vc) als Sonden zur cis/trans-Isomerisierung wurde festgestellt, dass die Diastereoselektivität der Epoxidierung nicht nur vom Gegenion des Mangankatalysators Ib, sondern auch von der eingesetzten Sauerstoffquelle [OxD] abhängt. Daher musste der Katalysezyklus (Schema A) um eine diastereoselektivitäts-bestimmende Gabelung erweitert werden: Das primär entstehende MnIII(OxD)-Addukt kann entweder unter Abspaltung der Fluchtgruppe zum etablierten MnV(oxo)-Komplex reagieren (Weg 1) oder direkt das Olefin epoxidieren (Weg 2). Während die Sauerstoffübertragung durch die Oxo-Spezies stufenweise über ein Radikalintermediat verläuft und damit zu einer Mischung aus cis- und trans-Epoxid führt, erfolgt der Lewisäure-aktivierte Sauerstofftransfer konzertiert. Der Gegenion-Effekt auf die cis/trans-Isomerisierung erklärt sich dahingehend, dass die Natur des Anions (koordinierend oder nicht-koordinierend) die Lebensdauer des Radikalintermediats und/oder die Lage und Selektivität der Energiehyperflächen der verschiedenen Spinzustände des MnV(oxo)-Oxidans beeinflusst. Fazit: In der Jacobsen-Katsuki-Epoxidierung existiert neben dem etablierten MnV(oxo)-Oxidans zumindest noch ein weiteres; dabei handelt es sich um das MnIII(OxD)-Addukt, dessen Sauerstoff Lewissäure-aktiviert übertragen wird. Ein unterschiedlicher Anteil der beiden Reaktionskanäle erklärt die Unterschiede im Ausmaß der cis/trans-Isomerisierung. Auch das Gegenion des Mangan-Komplexes Ib beeinflusst die cis/trans-Diastereoselektivität. Mit koordinierenden Gegenionen dominiert Isomerisierung zum trans-Epoxid, während nicht-koordinierende Gegenionen bevorzugt zum cis-Epoxid führen. / The aim of the present work was to explore the potential of chiral iron(porphyrin) and manganese(salen) complexes for the kinetic resolution of secondary allylic alcohols by asymmetric epoxidation. Furthermore, the mechanism of the Jacobsen-Katsuki epoxidation was investigated by elucidating the factors that determine the cis/trans diastereoselectivity in the epoxidation of cis olefins. A set of aryl-substituted racemic allylic alcohols IIa-f has been oxidized by the catalysts Ia and Ib,c with 0.8 or 0.6 equiv. of iodosyl benzene as oxygen source (eq. I) to effect kinetic resolution. For both catalysts, the oxidation is chemoselective (predominantly epoxidation) as well as diastereoselective (dr up to > 95:5), to afford the threo- or cis-configured epoxy alcohols III as main products. In this kinetic resolution, one enantiomer of the allylic alcohol II is preferentially epoxidized to give the corresponding epoxy alcohol III in ee values up to 80 per cent, the other enantiomer remains unreacted and is enriched (up to 53 per cent ee). Quite exceptional is 1,1-dimethyl-1,2-dihydro-2-naphthol (IIc), for which the CH oxidation dominates. The main difference between the iron and the manganese catalysts concerns their enantioselectivity: Whereas the Fe(porph*) complex Ia exhibits only moderate ee values of up to 43 per cent (krel up to 2.7), the Mn(salen*) complexes Ib,c provide enantioselectivities of up to 80 per cent ee (krel up to 12.9), which makes them useful catalysts for the kinetic resolution of the allylic alcohols II. The appreciable selectivities displayed for the manganese complexes Ib,c in these asymmetric epoxidations may be rationalized in terms of the synergistic interplay between the hydroxy-directing effect and the interactions of the catalyst and the substrate in the attack of the olefin along the Katsuki trajectory. Conclusion: The chiral Mn(salen*) complexes Ib,c are highly effective catalysts for the asymmetric epoxidation of the racemic allylic alcohols II. The respective epoxy alcohols III are formed in excellent chemo- and diastereoselectivitites with ee values up to 80 per cent, while the unreacted allylic alcohols are enriched up to 53 per cent ee. In comparison, the enantioselectivity for the iron catalyst Ia is much lower. The manganese-catalyzed oxidation of vinylcyclopropane Va reveals that radical intermediates are formed in the Jacobsen-Katsuki epoxidation rather than cationic ones, as has been confirmed through product studies by reversed-phase HPLC analysis. With cis-stilbene (Vb) and cis--methyl styrene (Vc) as mechanistic probes, it has been shown that the cis/trans diastereoselectivity of the Mn(salen)-catalyzed epoxidation depends not only on the counterion of the catalyst Ib, but also on the oxygen donor [OxD]. A diastereoselectivity-controlling bifurcation step needs to be added to the catalytic cycle (Scheme A), in which the initial MnIII(OxD) adduct may either split off its leaving group to form the established MnV(oxo) species (path 1) or epoxidize the olefin directly (path 2). The oxygen transfer by the oxo complex occurs stepwise through a radical intermediate and results in a mixture of the cis and trans epoxides; in contrast, the Lewis-acid-activated epoxidation is concerted. The effect of the counterion on the cis/trans diastereoselectivity may be explained in terms of whether the anion ligates to the metal. This affects the lifetime of the radical intermediate and/or the reaction profiles of the singlet, triplet and quintet spin states of the MnV(oxo) species, which in turn control the stereoselectivity. Conclusion: In addition to the established MnV(oxo) oxidant, at least one other oxidant has to be involved in the Jacobsen-Katsuki epoxidation; this species is proposed to be the MnIII(OxD) adduct that transfers its oxygen atom in a Lewis-acid activation. Varying proportions of the two oxygen-transfer pathways account for the cis/trans diastereoselectivities observed with the various oxygen donors. The cis/trans ratio also depends on the counterion of the manganese catalyst Ib: Whereas ligating counterions result in extensive cis/trans isomerization, with non-ligating counterions the formation of cis epoxides is strongly favored.

Mangan

Eisen

Epoxidation

Enantioselektivität

Katalyse

Allylalkohol

ddc:540

Catalytic Partial Oxidation Of Propylene On Metal Surfaces By Means Of Quantum Chemical Methods

Kizilkaya, Ali Can

01 February 2010

Direct, gas phase propylene epoxidation reactions are carried out on model slabs representing Ru-Cu(111) bimetallic and Cu(111) metallic catalyst surfaces with periodic Density Functional Theory (DFT) calculations. Ru-Cu(111) surface is modelled as a Cu(111) monolayer totally covering the surface of Ru(0001) surface underneath. The catalytic activity is evaluated following the generally accepted oxametallacycle mechanism. It is shown that the Ru-Cu(111) surface has a lower energy barrier (0.48 eV) for the stripping of the allylic hydrogen of propylene and a higher energy barrier (0.92 eV) towards propylene oxametallacycle (OMMP) formation compared to 0.75 eV barrier for OMMP formation and 0.83 eV barrier for allylic hydrogen stripping on Cu(111), and thus ineffective for propylene oxide production based on the investigated models and mechanism. In order to analyze the observed inability of the Ru-Cu(111) surface to selectively catalyze propylene oxide formation, a Lewis acid probe, SO2, was adsorbed on the oxygenated Cu(111) and Ru-Cu(111) surfaces and the binding energies, a measure of the basicity of the chemisorbed oxygen on the surfaces, on two systems are compared. As a conclusion, the reason behind this ineffectiveness of the Ru-Cu(111) surface for selectively catalyzing propylene epoxidation is related to the higher basicity of the atomic oxygen adsorbed on Ru-Cu(111) compared to the oxygen on Cu(111). The results are consistent both with recent publications about propylene epoxidation and previous studies performed about the structure of Ru-Cu catalysts.

QD Quantum Chemistry 462

Synthese nichtracemischer 1,2-N-O-Heterocyclen und Studien zu ihrer Eignung als Auxiliare in der asymmetrischen Aldoladdition

Hirn, Thomas.

Unknown Date

Techn. Universiẗat, Diss., 2007--Darmstadt.